Channel sounding for improved system performance

ABSTRACT

A transmitter generates and transmits a low rate signal to its intended receiver. Upon receiving the low rate signal, the intended receiver generates and transmits a channel sounding response (CSR), said CSR being a short burst having a predefined transmit format and carrying predetermined information. The transmitter then analyzes the CSR and determines uplink channel response, estimates downlink channel response, and determines appropriate transmit parameter settings based on the analysis and downlink response estimate. Adjustment of the transmit parameters can be made in either the MAC or PHY layer or in a combination of both. After adjusting its transmit parameters and modulating sub-carriers with user-data according to the determined transmit settings, the transmitter transmits the user-data to the receiver on a preferred portion of bandwidth. In a preferred embodiment, the transmitter also generates and transmits a transmit format control (TFC) signal containing the determined transmit parameter settings, including sub-carrier modulation information, to the receiver.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a Continuation application of U.S. application Ser.No. 13/960,071 filed Aug. 6, 2013; which is a division of U.S.application Ser. No. 11/201,676, now U.S. Pat. No. 8,531,937; and claimsthe benefit of U.S. Provisional Application No. 60/600,739 filed Aug.11, 2004, each of which are incorporated by reference as if fully setforth.

FIELD OF INVENTION

The present invention relates to wireless communication systems. Moreparticularly, the present invention is a method and apparatus forimproving channel and system performance in a wireless communicationsystem.

BACKGROUND

Orthogonal Frequency Division Multiplexing (OFDM) refers to a datatransmission scheme wherein user-data is split into smaller data streamsand transmitted using sub-carriers that each has a smaller bandwidththan the total available transmission bandwidth. The efficiency of OFDMresults from the orthogonality of the sub-carriers. That is to say, thesub-carriers are selected such that they do not interfere with eachother during transmission, thus resulting in an efficient transmissionscheme.

Multiple-Input Multiple-Output (MIMO) refers to a wireless transmissionand reception scheme wherein both transmitter(s) and receiver(s) employmultiple antennas for transmission and reception. A MIMO system takesadvantage of the spatial diversity or spatial multiplexing optionscreated by the presence of the multiple antennas to increase throughput.

A continuing challenge for OFDM-MIMO systems is system performance,i.e., capacity, reliability, etc. Towards this end, many techniques havebeen proposed for improving, for instance, channel capacity and/orreliability. An example of one such technique is referred to as“water-filling”, another example is power control. Water-filling andpower control describe processes whereby a transmitter estimates channelconditions using feedback signals from a receiver in the system. Basedon these estimates, the transmitter attempts to transmit user data in away that optimizes channel performance in view of the channelconditions. As with similar techniques, water-filling and power controlrely upon knowledge of the transmission channel, via feedback signals,to optimize channel performance. The signaling overhead associated withthese feedback signals, however, is significant and often limits anypotential increase in system performance. In addition, generating andtransmitting feedback signals causes delays which also limit potentialincreases in system performance. These drawbacks to feedback signalingare particularly evident in systems with rapidly changing channelconditions, systems transmitting large amounts of data, and/or systemsutilizing a large number of sub-carriers.

Accordingly, it is desirable to have a method and apparatus forefficiently estimating current channel conditions for use in improvingoverall system performance in OFDM-MIMO systems.

SUMMARY

The present invention is a method and apparatus for improving systemperformance in Multiple-Input, Multiple-Output (MIMO) OrthogonalFrequency Division Multiplexing (OFDM) wireless communication systems. Atransmitter generates and transmits a low rate signal to its intendedreceiver. Upon receiving the low rate signal, the intended receivergenerates and transmits a channel sounding response (CSR), said CSRbeing a short burst having a predefined transmit format and carryingpredetermined information. The transmitter then analyzes the CSR anddetermines uplink channel response, estimates downlink channel response,and determines appropriate transmit parameter settings based on theanalysis and downlink response estimate. Adjustment of the transmitparameters can be made in either the MAC or PHY layer or in acombination of both. After adjusting its transmit parameters andmodulating sub-carriers with user-data according to the determinedtransmit settings, the transmitter transmits the user-data to thereceiver on a preferred portion of bandwidth. In a preferred embodiment,the transmitter also generates and transmits a transmit format control(TFC) signal containing the determined transmit parameter settings,including sub-carrier modulation information, to the receiver.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a flow diagram illustrating a channel sounding scheme forimproving system performance in Multiple-Input, Multiple-Output (MIMO)Orthogonal Frequency Division Multiplexing (OFDM) communication systems;

FIG. 2 is a MIMO-OFDM transmitter-receiver pair configured to usechannel sounding pulses to improve system performance; and

FIG. 3 is MIMO-OFDM wireless communication system wherein a base stationand a wireless transmit/receive unit (WTRU) each comprise atransmitter-receiver pair in accordance with the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Herein, a wireless transmit/receive unit (WTRU) includes but is notlimited to a user equipment, mobile station, fixed or mobile subscriberunit, pager, or any other type of device capable of operating in awireless environment. When referred to herein, a base station includesbut is not limited to a Node-B, site controller, access point or anyother type of interfacing device in a wireless environment.

In a preferred embodiment, channel sounding pulses are used forimproving channel and system performance in Orthogonal FrequencyDivision Multiplexing (OFDM) systems utilizing Multiple-Input,Multiple-Output (MIMO) equipment. The sounding pulses enable MIMO-OFDMtransmitters, for instance, to assess current channel conditions andhence, to format transmit data packets that optimize throughput in viewof the channel conditions.

In accordance with the present embodiment, a MIMO-OFDM transmittergenerates and transmits a low rate signal, such as a request for asounding pulse (CSRq) to an intended receiver. Upon receiving thisrequest, the receiver generates a channel sounding response (CSR) andtransmits it to the requesting transmitter. This CSR is preferably ashort burst formatted with predetermined transmit parameters that assureits successful reception given the particular system configuration andenvironment. Included in the CSR is information known to thetransmitter. The transmitter, upon receiving the CSR, processes theinformation and determines current channel conditions. Based on thesedeterminations, the transmitter modulates user data to sub-carriers andadjusts its transmit parameters to maximize channel capacity,reliability, and/or any other channel performance characteristic asrequired by a user, using any of the various channel optimizationtechniques including water-filling and power control. Utilizing CSRpulses to assess channel conditions, rather than conventional feedbacksignals, enables the transmitter to format and transmit data packetsthat optimize channel performance without incurring all of the overheadand delay of conventional channel-improvement approaches.

Referring now to FIG. 1, a flow diagram 100 illustrating a channelsounding scheme for improving system performance in MIMO-OFDM wirelesscommunication systems is shown. Prior to transmitting data, atransmitter generates a channel sounding response request in the form ofa low rate signal and transmits it to a receiver (step 102). Thisrequest is preferably a low data rate signal, such as a data packetheader, containing source (i.e., transmitter) and destination (i.e.,intended receiver) information. Upon receiving and processing the lowrate signal (step 104), the receiver generates and transmits apredefined channel sounding response (CSR) (step 106), preferably as ashort burst or pulse, to the transmitter. The CSR is preferablypredefined in terms of its size, number of symbols, amplitude, etc., toassure successful reception at the transmitter given the particularsystem configuration and/or the receiver's allocated resources. Includedin the CSR is information the transmitter may use in assessing currentchannel conditions.

At the transmitter, the CSR is received and information transmitted aspart of the CSR is processed (step 108) and utilized to characterize thecurrent channel conditions (step 110). This characterization includesdetermining uplink channel response via measuring the amplitude, phase,and quality of each received sub-carrier at each antenna; and estimatingdownlink channel response. If a particular sub-carrier indicates a higherror rate, for instance, the transmitter will not modulate thatsub-carrier with large amounts of data. Conversely, if a particularsub-carrier arrives at the transmitter with a relatively low error rate,the transmitter will more heavily modulate that sub-carrier with userdata.

Once the channel conditions are known in the uplink and estimated forthe downlink (step 110), the transmitter determines appropriate transmitparameter settings (step 112), (e.g., antenna selection, antenna power,bandwidth selection, carrier power, carrier coding, carrier modulation,etc.), makes the appropriate parameter adjustments (step 114), andaccordingly modulates its sub-carriers (step 116), preferably using awater-filling, power control, or similar technique. It should be notedthat the parameter adjustments may occur in the MAC layer, in the PHYlayer, or in a combination of the two. The formatted data packets arethen transmitted on select portion of bandwidth to the receiver (step118). Optionally, the transmitter tracks the channel performanceestimates derived from current and previous CSR measurements (step 112a), enabling the transmitter to predict future channel conditions foruse in optimizing the channel performance of future data transmissions.

It should be understood that the overall channel performance of acommunication link remains relatively static even though the performanceof a particular sub-carrier and/or antenna pair may change quiterapidly. This is particularly true if the communication link hassufficient bandwidth and spatial diversity. Accordingly, the size of thetransmitted data packets may be fixed, leaving only the encodingparameters to be adjusted, which can occur in near real time based onreceived CSRs. Transmitting fixed-sized data packets greatly simplifiesthe MAC layer's complexity. There is, however, some added complexityrequired in the PHY layer, particularly if the PHY layer is configuredto determine and implement the final encoding scheme

Prior to, after, or in parallel with transmitting the formatted datapackets (step 118), the transmitter may optionally generate and send atransmit format control (TFC) signal to the receiver (step 120). ThisTFC signal includes information regarding the transmit parametersettings and identifies which sub-carriers have been modulated by whichmodulation schemes (e.g., QPSK, 16 QAM, 256 QAM, etc.), and/or whichcoding types and data rates have been used. Providing this type ofinformation to the receiver as part of the TFC signal is an enhancementwhich simplifies overall receiver decoding complexity. Alternatively, ifa TFC signal is not generated or not successfully received at thereceiver, the receiver may determine TFC information on its own via atrial and error method, hereinafter referred to as “blind TFCdetection”.

To further improve the overall system performance, the transmitterand/or receiver may monitor CSR signals emitted by other receiver(s) inthe system, assess the communication link between themselves and thereceiver(s) emitting the CSRs, and maintain a history of these channelconditions for use in future communications with that receiver.

Referring now to FIG. 2, a MIMO-OFDM transmitter 202 and receiver 204configured in accordance with the present invention are shown. Includedin the transmitter 202 is a channel sounding signal processor 201 forgenerating low rate sounding request signals, for processing receivedchannel sounding response signals, and preferably, for assessing channelconditions of a communication link between itself and receivers. Inaddition, the transmitter 202 includes a MAC layer processor 203 forsetting data transmit parameters including data rates, coding schemes,packet formats, etc., a physical (PHY) layer processor 205 for spreadingdata bits across sub-carriers and across transmit antennas 207 ₁, 207 ₂,. . . 207 _(n) according to the MAC parameter setting processor 203 oroptionally, according to the PHY layer processor's 205 own transmitparameter settings, an optional transmit format control (TFC) processor206 for processing information from the MAC processor 203 and/or the PHYlayer processor 205, an optional signal monitoring processor 208 formonitoring CSR signals transmitted between other receiver-transmitterpairs, an optional memory component 210 for maintaining a history ofchannel conditions and determined transmit parameters, and a pluralityof transmit/receive antennas 207 ₁, 207 ₂, . . . 207 _(n).

Included in the receiver 204 is a plurality of transmit/receive antennas209 ₁, 209 ₂, . . . 209 _(n), a channel sounding processor 211 forprocessing channel low rate sounding requests, for generating channelsounding response (CSR) signals, and preferably, for assessing channelconditions of a communication link between itself and other transmittersand/or receivers. In addition, the receiver 204 includes an optional TFCprocessor 213 for processing received TFC control information and fordetermining TFC information via blind detection, a data packet processor215 for decoding and demodulating received data packets according to theinformation provided by the TFC processor 213, an optional signalmonitoring processor 217 for monitoring CSR signals transmitted fromother receivers, a memory component 219 for maintaining a history ofchannel conditions, and an optional adjustment processor 221 foradjusting transmit parameters based on the channel history.

For clarity and solely for illustrative purposes, the transmitter 202and the receiver 204 shown in FIG. 2 are hereinafter described asseparate devices operating independently in a MIMO-OFDM system. Itshould be understood, however, that these devices 202, 204 arepreferably configured to co-exist as inter-related components of asingle MIMO-OFDM network device, such as a base station or a WTRU, asshown in FIG. 3. The MIMO-OFDM wireless communication system 300 of FIG.3 comprises a base station 301 and WTRU 302 communicating over awireless interface, and an RNC 250 for controlling the base station 301.As the Figure illustrates, both the base station 301 and WTRU comprise atransmitter 202—receiver 204 pair configured in accordance with thepresent invention.

Referring back to FIG. 2, in the transmitter 202, prior to processing adata stream Tx for transmission, a low rate channel sounding requestsignal is generated in the channel sounding signal processor 201. Thissounding request is then passed to the transmit antennas 207 ₁, 207 ₂, .. . 207 _(n) for transmission to the receiver 204 via a wirelessinterface. Upon receiving the low rate request, the receiver 204processes the request and generates a channel sounding response (CSR) inits channel sounding processor 211. As described above, the CSR ispreferably a short burst formatted to assure reception at thetransmitter 202 and includes information known to the transmitter 202for use in assessing current channel conditions. Once generated, the CSRis sent to the receiver's antennas 209 ₁, 209 ₂, . . . 209 _(n) fortransmission to the transmitter 202.

The CSR is then received at the transmitter 202 and processed in thetransmitter's channel sounding processor 201. The channel soundingprocessor 201 analyzes the information transmitted as part of the CSRand uses this information to characterize current channel conditions inthe uplink, and to estimate downlink channel response. These channelcharacterizations are then sent to the MAC layer processor 203 and/or tothe PHY layer processor 205 where they are used to set data transmitparameters including: sub-carrier allocation, transmit antennaallocation, sub-carrier transmit power, transmit antenna power,sub-carrier coding, bandwidth selection, etc. Optionally, with regard toselecting a desired portion of bandwidth on which to transmit, thetransmitter 202 may comprise a separate processor (not shown) configuredto operate as a bandwidth selection unit. The PHY layer processor 205then formats the transmit data packets, modulates the varioussub-carriers (not shown) with user data, and maps the modulatedsub-carriers to the transmit/receive antennas 207 ₁, 207 ₂, . . . 207_(n), using a channel capacity optimization scheme, such aswater-filling, a channel reliability optimization scheme, or any otherchannel performance optimizing scheme in accordance with the transmitparameter settings. The formatted data packets are sent to thetransmit/receive antennas 207 ₁, 207 ₂, . . . 207 _(n) for transmissionto the receiver 204 using preferred portions of the bandwidth.Optionally, the transmitter 202 maintains a history of channel conditionestimates for use in optimally transmitting future data packets.

Prior to, after, or in parallel with transmitting the formatted datapackets, the optional TFC processor 206 generates and transmits a TFCsignal via the transmit/receive antennas 207 ₁, 207 ₂, . . . 207 _(n)over the wireless interface. This TFC signal indicates to the receiver204 the transmit parameter settings of the transmitted data packets andidentifies the location (i.e., on which sub-carriers the data bits arebeing transmitted), the coding schemes and the modulation schemes (e.g.,QPSK, 16 QAM, etc.) used for the transmitted data packets.

If a TFC signal is transmitted, the receiver 204, receives the TFCsignal and processes it in its optional TFC processor 213. This TFCprocessor 213 extracts the formatting and modulation information fromthe TFC signal and sends it to the data packet processor 215 for use indecoding and demodulating received data packets. Otherwise, if a TFCsignal is not successfully detected by the receiver 204, the TFCprocessor 213 gathers available TFC information using a blinddetection-type process.

To further improve system capacity and efficiency, the transmitter 202and receiver 204 can monitor the CSRs generated by other receivers (notshown) using their respective signal monitoring processors 208, 217 andthereafter, assess and estimate the channel conditions betweenthemselves and the other receiver(s). In the transmitter 202 and thereceiver 204, their respective channel sounding processors 201, 211 maybe configured to perform these channel assessments and estimates.Alternatively, the transmitter 202 and receiver 204 may each compriseadditional processors (not shown) configured to function as a signalanalyzer that assesses uplink channel conditions and as an estimator forestimating downlink channel conditions based on the channel assessments,respectively. This channel condition information may be utilized by boththe transmitter 202 and receiver 204 to maintain a history of thechannel conditions for use in determining transmit parameters of futurecommunications with the receiver(s). This history may be stored in theirrespective memory components 210, 219.

In accordance with the present invention, the transmitter 202 may reusethe transmit parameter settings, preferably stored in the optionalmemory component 210, as set by the MAC layer processor 203 and/or thePHY layer processor 205 for subsequent data transmissions such time thata future CSR indicates a change in channel conditions. Alternatively,the transmitter 202 may use historical results from previously receivedCSR(s), also stored in the optional memory component 210 or in asecondary memory component (not shown), to predict when a change inchannel conditions will occur and at that time, adjust the transmitparameters accordingly. Similarly, the receiver 204 may maintain ahistory of channel conditions in its optional memory component 219 foruse in adjusting transmit parameters via its optional adjustmentprocessor 221.

Although not particularly specified, the frequency at which atransmitter requests channel sounding information from a receiverdepends on a variety of factors. Examples of such factors include, butare not limited to: system configuration, number of sub-carriers, numberof spatial channels, volatility of the communication link, communicationenvironment, and the like. In general terms, a transmitter must requesta CSR often enough to maintain accurate knowledge of the channel. As anexample, a transmitter may begin by requesting CSRs at predeterminedtime intervals. As the transmitter begins to accumulate CSR data, thetransmitter may use this data to estimate the rate at which channelconditions change and accordingly request CSRs according to the changefrequency.

The present invention may be implemented in any type of wirelesscommunication system, as desired. By way of example, the presentinvention may be implemented in any type of 802-type system, UMTS-FDD,UMTS-TDD, TDSCDMA, CDMA2000, OFDM-MIMO or any other type of wirelesscommunication system. The present invention may also be implemented onan integrated circuit, such as an application specific integratedcircuit (ASIC), multiple integrated circuits, logical programmable gatearray (LPGA), multiple LPGAs, discrete components, or a combination ofintegrated circuit(s), LPGA(s), and discrete component(s).

While the present invention has been described in terms of variousembodiments, other variations, which are within the scope of theinvention, as outlined in the claims below, will be apparent to thoseskilled in the art. Further, although the features and elements of thepresent invention are described in the various embodiments in particularcombinations, each feature or element can be used alone (without theother features and elements of the preferred embodiments) or in variouscombinations with or without other features and elements of the presentinvention.

1. A wireless communications method for a base station, the methodcomprising: transmitting a channel sounding response request (CSRq) in adownlink channel to a wireless transmit/receive unit (WTRU), wherein theCSRq comprises channel sounding instructions; receiving an uplinkchannel sounding response (CSR) responsive to the CSRq, the CSR beingdefined in terms of the number of symbols, size and symbol amplitude;determining a multiple-input multiple output (MIMO) uplink channelresponse via measuring the amplitude and phase of subcarriers of the CSRat a plurality of antennas; determining, based on the MIMO uplinkchannel response, downlink transmit parameter settings, includingmodulation and coding parameters, for each of a plurality of subcarriersto be transmitted on by the base station; and transmitting thedetermined downlink transmit parameter settings to the WTRU.
 2. Themethod of claim 1 further comprising: determining the plurality ofsub-carriers to be transmitted on based on the MIMO uplink channelresponse.
 3. The method of claim 1 wherein the channel capacityoptimization technique is power control.
 4. The method of claim 1wherein the determined transmit parameters settings are transmitted tothe WTRU using a transmit format TF signal.
 5. The method of claim 4wherein the TF signal includes power control parameters.
 6. The methodof claim 1 wherein the size of the CSR is the number of subcarriers. 7.A base station for use in wireless communications comprising: atransmitter configured to transmit a channel sounding response request(CSRq) in a downlink channel to a wireless transmit/receive unit (WTRU),wherein the CSRq comprises channel sounding instructions; a receiverconfigured to receive an uplink channel sounding response (CSR)responsive to the channel sounding instructions, wherein the CSR isdefined in terms of the number of symbols, size and symbol amplitude;and a processor configured to determine a multiple-input multiple output(MIMO) uplink channel response via measuring the amplitude and phase ofsubcarriers of the CSR at a plurality of antennas and to determine,based on the MIMO uplink channel response, downlink transmit parameterssettings, including modulation and coding parameters, for each of aplurality of subcarriers to be transmitted on by the base station;wherein the transmitter is further configured to transmit the determineddownlink transmit parameter settings to the WTRU.
 8. The base station ofclaim 7 wherein the processor is further configured to determine theplurality of sub-carriers to be transmitted on based on the MIMO uplinkchannel response.
 9. The base station of claim 7 wherein the determinedtransmit parameter settings are transmitted to the WTRU using a TFsignal.
 10. The base station claim 9 wherein the TF signal includespower control parameters.
 11. The base station of claim 7 wherein thesize of the CSR is the number of subcarriers.
 12. A wireless transmitreceive unit (WTRU) comprising: a receiver configured to receive achannel sounding response request (CSRq) on a downlink channel, the CSRqcomprising channel sounding instructions; and a transmitter configuredto transmit on an uplink channel a channel sounding response (CSR)responsive to the channel sounding instructions, wherein the CSR isdefined in terms of the number of symbols, size and symbol amplitude;the receiver further configured to receive downlink transmit parametersettings, including modulation and coding parameters, for each of theplurality of sub-carriers to be transmitted on by the base station usingat least one of a plurality of antennas.
 13. The WTRU of claim 12wherein the transmit parameter settings further include the plurality ofsub-carriers to be transmitted on.
 14. The WTRU of claim 12 wherein thedetermined transmit parameters settings are received in a transmitformat (TF) signal.
 15. The WTRU of claim 14 wherein the TF signalincludes power control parameters.
 16. The WTRU of claim 12 wherein thesize of the CSR is the number of subcarriers.
 17. A wirelesscommunications method for a wireless transmit receive unit (WTRU), themethod comprising receiving a channel sounding response request (CSRq)on a downlink channel, the CSRq comprising channel soundinginstructions; transmitting on an uplink channel a channel soundingresponse (CSR) responsive to the channel sounding instructions, whereinthe CSR is defined in terms of the number of symbols, size and symbolamplitude; and receiving downlink transmit parameter settings, includingmodulation and coding parameters, for each of a plurality ofsub-carriers to be transmitted on by the base station using at least oneof a plurality of antennas.
 18. The method of claim 17 wherein thetransmit parameter settings further include the plurality ofsub-carriers to be transmitted on.
 19. The method of claim 17 whereinthe determined transmit parameters settings are received in a transmitformat (TF) signal.
 20. The method of claim 19 wherein the TF signalincludes power control parameters.
 21. The method of claim 19 whereinthe size of the CSR is the number of subcarriers.